Device for filling a cigarette tube with a metered amount of tobacco

ABSTRACT

Devices for filling a cigarette tube with tobacco are disclosed. In one aspect, the devices contain separate metering, compression, and injection mechanisms, which may be manual, partially automatic, or fully automatic. The metering mechanisms move a proper amount of tobacco to a compression chamber, where the tobacco is thereafter compressed for eventual injection. In some embodiments, means are provided for assessing whether a sufficient quantity of tobacco has been metered into the compression chamber, and if not, further metering is accomplished prior to injection. In another aspect, the metering and compression mechanisms are combined into a single mechanism to the same effect. In yet another aspect, a loader for holding cigarette tubes is provided that can be manually operated or fully automated.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation-in-part of U.S. patent application Ser. No. 10/893,606, filed Jul. 16, 2004, which is a divisional of U.S. patent application Ser. No. 10/714,359, filed Nov. 14, 2003, now U.S. Pat. No. 6,913,022, which claims priority to U.S. Provisional Patent Application Ser. No. 60/428,199, filed Nov. 21, 2002, and this application claims priority to each of these applications.

FIELD OF THE INVENTION

The present invention relates generally to a device for filling cigarette tubes with tobacco, and more particularly to a fully manual, partially automated, or fully automated device for filling cigarette tubes with metered amounts of tobacco.

BACKGROUND OF THE INVENTION

Cigarette tubes generally comprise a paper cylinder having an open end and a filter end. Various machines exist in the market for allowing a user to fill such tubes with loose tobacco to make their own cigarettes.

An example of a prior art cigarette tube filing machine includes the Supermatic II device distributed by Jack Gee's Sales (see http://www.jackgee.com/supermatic_ii.htm). Composition of the internal portions of this device can be found at the following websites: http://www.jackgee.com/parts.htm and http://www.ryomagazine.com/july2001/injectors.htm. This tabletop device is hand crank operated and includes an open rectangular compression chamber on the top of the device into which a user places tobacco to be compressed and formed into a cigarette. The operator turns the hand crank clockwise to compress and eventually inject the compressed tobacco into a cigarette tube affixed to a nozzle on the exterior housing of the device. More specifically, when the user turns the hand crank from its rest position through approximately 90 degrees, a compression slide is moved linearly towards the compression chamber and eventually compresses the tobacco in the chamber into a cylinder to form a plug of tobaaco. Thereafter when the hand crank is turned further, through approximately an additional sixty degrees, a mechanism on the hand crank contacts a linear injection slide. This injection slide moves perpendicular to the now-stationary compression slide and parallel to the affixed cigarette tube to push the compressed tobacco plug through the compression chamber and into the waiting cigarette tube.

A similar but automated device is the MackRoller device, distributed by the CigFactory (see http://www.webbspot.com/mackroller/). This device is electrically automated, and allows the user to merely place the cigarette tube on the device, turn on a switch, and compression and injection are performed automatically. However, the MackRoller device appears similar in its structure and internal mechanisms to Supermatic II, with the exception that the hand crank has been replaced by a motor to provide the necessary rotational movement. Videos showing the operation of the MackRoller device can be found at http://www.webbspot.com/mackroller/cigarette_rolling_machine_vide4.html. All websites and associated videos disclosed in this background section are incorporated by reference herein in their entireties.

Another automated device for filling cigarette tube with tobacco includes the EasyRoller device manufactured by CP Rollings ApS of Denmark. This device is also automated and can fill an affixed cigarette tube by merely pushing a button. The device essentially comprises a motor with a screw mechanism affixed to its rotor. The screw mechanism is placed at the bottom of a tobacco hopper for holding loose tobacco and continues through a metal tube onto which the cigarette tube is affixed. When operated, the screw mechanism turns to direct tobacco from the hopper and to compact or “screw” it into the waiting cigarette tube.

These and other cigarette tube filling devices are disclosed in the Information Disclosure Statement that the inventors have filed with this patent application, all of which are incorporated herein by reference. However, none of these devices are believed suitable to service the “roll your own” cigarette market, as they each suffer various drawbacks: some machines are dangerous; others do not adequately fill the cigarette tubes, or do so loosely and irregularly; some do not fill tubes with adequate speed, etc.

Moreover, a problem that seems pervasive in the cigarette tube filling art is that such machines lack the ability to fill tubes with a precise quantity of tobacco on a consistent basis. The Supermatic II and MackRoller device discussed earlier provide a good illustration of this problem. Although such devices can generally adequately compress and inject tobacco into waiting tubes, they depend on the user of the machine to adequately fill the compression chamber with a sufficient amount of tobacco by essentially stuffing some amount of tobacco into the chamber by hand. The machine thus has no means to automate, or meter, a proper amount of tobacco for eventual injection inside of the tubes. Moreover, such devices generally lack means to deal with different cuts of cigarette tobacco, such as shag cut or bulk cut, or tobaccos of various moisture contents, etc. The result is generally the formation of cigarettes which are uneven or incomplete in their density, and/or which may not burn properly or fall apart when burned, which cigarette smokers generally find undesirable.

The present disclosure provides several different embodiments of cigarette tube filling machines which overcome or mitigate such problems of the prior art. In particular, the disclosed machines, amongst other benefits, contain mechanisms for metering a proper amount of tobacco to be compressed and eventually injected. Whether fully manual, partially automatic, or fully automatic versions of the disclosed machine are used, the result is the formation of cigarettes which contain consistent and even amounts of tobacco.

SUMMARY OF THE INVENTION

Devices for filling a cigarette tube with tobacco are disclosed. In one aspect, the devices contain separate metering, compression, and injection mechanisms, which may be manual, partially automatic, or fully automatic. The metering mechanisms move a proper amount of tobacco to a compression chamber, where the tobacco is thereafter compressed for eventual injection. In some embodiments, means are provided for assessing whether a sufficient quantity of tobacco has been metered into the compression chamber, and if not, further metering is accomplished prior to injection. In another aspect, the metering and compression mechanisms are combined into a single mechanism to the same effect.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing embodiments of the invention will be best understood with reference to the following detailed description when read in conjunction with the accompanying drawings, in which:

FIGS. 1A-1D illustrate various views of a first embodiment of a device for filling cigarette tubes with metered amounts of tobacco, wherein the disclosed device has an automated metering unit.

FIGS. 2A-2B illustrate various views of the first embodiment in a stage of operation in which an amount of tobacco is being metered.

FIGS. 3A-3B illustrates various views of the first embodiment in a further stage of operation in which the metered amount of tobacco is being compressed.

FIG. 4 illustrates a partially exposed front view of the first embodiment in a yet further stage of operation in which the metered and compressed tobacco is injected into a cigarette tube.

FIGS. 5A-5B illustrate second embodiments of manually operated devices for filling cigarette tubes with metered amounts of tobacco.

FIG. 6A illustrates a third embodiment of an automated device for filling cigarette tubes with metered amounts of tobacco.

FIG. 6B illustrates a schematic of a control unit for the device of FIG. 6A.

FIG. 7 illustrates a fourth embodiment of an automated device for filling cigarette tubes with metered amounts of tobacco.

FIG. 8 illustrates a fifth embodiment of an automated device for filling cigarette tubes with metered amounts of tobacco capable of detecting the sufficiency of the quantity of metered tobacco and adjusting that quantity if necessary.

FIGS. 9A-9C illustrate a sixth embodiment of an automated device for filling cigarette tubes with metered amounts of tobacco having an improved capability for detecting the sufficiency of the quantity of metered tobacco and adjusting that quantity if necessary.

FIGS. 10A-10B illustrate a seventh embodiment of an automated device for filling cigarette tubes with metered amounts of tobacco in which metering and compression are integrated.

FIGS. 10C-10E illustrate details of a metering/compression member useable with the seventh embodiment.

FIGS. 11A-11D illustrate an eighth embodiment of an automated device for filling cigarette tubes with metered amounts of tobacco in which metering and compression are integrated.

FIGS. 12A-12H illustrate various views of a ninth embodiment of an automated device for filling cigarette tubes with metered amounts of tobacco.

FIGS. 13A-13B illustrate a tenth embodiment of an automated device for filling cigarette tubes with metered amounts of tobacco where an automated loader holds the cigarette tubes.

FIGS. 14A-14B illustrate detailed views the automated loader of FIGS. 13A-13B.

FIGS. 15A-15C illustrate views of the automated loader and the automated device of FIGS. 13A-13B.

FIGS. 16A-16B illustrate an embodiment of a manual loader for the automated device.

FIGS. 17A-17B illustrate embodiments of additional automated loaders for the automated device.

DETAILED DESCRIPTION OF THE INVENTION I. First Embodiment

Referring to FIGS. 1A-1D, a first embodiment of a partially-automated device 10 for filling cigarette tubes 70 with a measured or metered amount of tobacco 76 is illustrated. In this first embodiment, the metering of the tobacco is automated, while compression and injection are manual, as will be explained in further detail later.

The disclosed device 10 is illustrated in a front elevational view in FIG. 1A and in a side elevational view in FIG. 1B. In FIG. 1C, the disclosed device is illustrated in a side cross-sectional view. In FIG. 1D, the disclosed device 10 is illustrated in a plan view in broken cross-section. The disclosed device 10 is depicted in a basic form to show the gross anatomy of the device. However, it may be aesthetically designed or altered by one of ordinary skill in the art.

The disclosed device 10 includes a body 11, a hopper unit 20, a metering unit 30, a compressing unit 80, a cigarette tube magazine 130, an injecting unit 150, and a clamping unit 180. The disclosed device 10 is preferably sized to sit on a table for easy use by a “roll your own” smoker. However, the disclosed device 10 could be made larger or smaller to fit a desired implementation, or could be used in a manufacturing or production environment. The various components of the disclosed device 10 can be composed of suitable metals and/or plastics. Preferably, high stress or wear prone components are composed of metal. Furthermore, slideable components preferably use metal to plastic or plastic-to-plastic interfaces which do not require the addition of oil or grease.

The hopper unit 20 as best shown in FIG. 1C is formed in the body 11 and is used to store and deliver tobacco 76 to the metering unit 30. In turn, the metering unit 30 is used to meter or measure tobacco 76 from the hopper 20 to the compressing unit 80 and injecting unit 150. The compressing unit 80 is used to compress the tobacco 76, and the injecting unit 150 is used to insert a resulting compressed plug of tobacco 76 into a cigarette tube 70 positioned on the magazine 130 (FIG. 1D). The clamping unit 180, as best shown in FIG. 1B, is used to firmly hold an open end of the cigarette paper portion 72 (FIG. 1A) of the cigarette tube 70 adjacent the injecting unit 150 during insertion of the compressed plug of tobacco 76. Such tubes 70 also usually contain a filter 74.

The body 11 (FIG. 1B) has first and second sidewalls 12 and 14 (FIG. 1A), which are used to contain and mount the various components of the device 10. The hopper 20 is formed in the body 11 between the sidewalls 12 and 14. As best shown in FIG. 1C, the hopper 20 has a first or lower surface 21, a first funnel wall 22, and a baffle unit 24. The baffle unit 24 has a second funnel wall 26 and a third holding wall 28. The funnel walls 22, 26, and 28 are preferably angled at approximately 45-degrees with respect to the lower surface 21 of the hopper 20 as shown. In a preferred embodiment, the first funnel wall 22 and the holding wall 28 define a horizontal gap G of approximately 1-inch, and the lower surface 21 of the hopper 20 defines a surface area of approximately 4 square inches.

Loose tobacco 76 is placed in the hopper 20, and the walls 22, 26, and 28 direct the loose tobacco 76 towards the lower surface 21 of the hopper 20 where the metering device 30 is located. Because loose tobacco 76 is composed of flat shreds or cuts of tobacco, it may tend to bunch up or clog, which may prevent the metering plate 40 from adequately passing the loose tobacco to the compression chamber 90, as is described in more detail below. The baffle unit 24 is particularly suitable for preventing such an occurrence. The funnel walls 22 and 26 limit the volume of loose tobacco capable of positioning at the bottom of the hopper 20. In addition, the holding wall 28 holds the loose tobacco 76 adjacent the lower surface 21 of the hopper 20 when the metering unit 30 is operating. The baffle unit 24 is preferably capable of holding an approximately 1-inch layer of tobacco adjacent the lower surface 21 of the hopper 20.

Although not shown in the figures, other schemes may be employed to bias the loose tobacco 76 downward in the hopper 20. For example, a floating weight may be placed on top of the tobacco in the hopper 20, or a spring biased panel or level may be used to push the tobacco downward. Such a spring biased device could also be incorporated into a cover for the top of the hopper or could be attached inside of the hopper 20. In any event, there are many different ways to bias the tobacco downward as one skilled in the art will recognize, and in this regard the baffle structure is not strictly necessary. Instead, the hopper 20 may be built essentially as a box with vertical or substantially vertical sidewalls, and not even require a downward biasing scheme if the weight of the tobacco in the hopper is sufficient for proper operation.

As best shown in FIG. 1C, the metering unit 30 includes an outer housing 31, upper and lower guide surfaces 32 and 34, a metering plate 40, and a shear plate 46. The metering unit 30 also includes an automated metering actuator 50 having a motor 52, a gearbox 54, and a slide crank 56, which are not shown in cross-section in FIG. 1C for clarity. The metering unit 30 also includes a control unit 60, which is shown in FIG. 1D and is attached to the second sidewall 14.

As best shown in FIG. 1C, the metering plate 40 is positioned between the first and second guide surfaces 32 and 34. The first guide surface 32 terminates at the lower funnel wall 22. The second guide surface 34 extends towards the compressing unit 80. One end 42 (see FIG. 1D) of the metering plate 40 is adjacent the tobacco 76 in the hopper 20 and is movable relative to the shear plate 46. The shear plate 46 is oriented substantially perpendicular to the metering plate 40 and is positioned adjacent the compressing unit 80 as described below.

As best shown in the top view of FIG. 1D, the one end 42 of the plate is preferably serrated and beveled. The serrated end 42 is used for agitating and cutting the loose tobacco. For example, the serrated end 42 is capable of catching the loose shreds of tobacco 76 at the bottom of the hopper 20 and cutting the shreds against the shear plate 46 (see FIG. 1C). The metering plate 40 contains a lateral slot 44 for an eccentrically located pin 58 on the slide crank 56. Another end 48 of the metering plate 40 abuts against a counting switch 64 when the metering plate is set in motion by the control unit 60. The metering plate 40 preferably has a thickness of approximately 0.06-inch and a width of approximately 2.7-inch along its serrated end 42.

As best shown in FIG. 1C, the motor 52 and gearbox 54 are attached to a metering mount 18 connected between the sidewalls of the device. The motor 52 and gearbox 54 connect to the slide crank 56. The eccentrically located pin 58 on the slide crank 56 is disposed in the lateral slot 44 defined in the metering plate 40. Rotation of the motor 52 is transferred through the gearbox 54 to the slide crank 56 such that when the slide crank 56 is rotated, the eccentrically located pin 58 in slot 44 repetitively moves the metering plate 40 back and forth between the guide surfaces 32 and 34. As noted above, the slot 44 where the eccentric pin 58 of the slide crank 56 is inserted is defined laterally in the plate 40. Thus, as the eccentric pin 58 is rotated with the slide crank 56, the pin 58 will move the plate 40 back and forth longitudinally (i.e., left to right in FIGS. 1C and 1D) but not laterally.

The motor 52 can be a conventional DC motor used in household appliances or office equipment. In one example, a 12-V DC motor having model no. RS-385SH and manufactured by Mabuchi Motors can be used. This DC motor can provide torque of approximately 72.9 g-cm at maximum efficiency. Use of the gearbox 54 is preferred with the motor 52, although this may not be strictly necessary depending on the motor or actuator used. Preferably, the motor 52 and gearbox 54 are capable of providing about 10 in-lbs. of torque. One of ordinary skill in the art, however, will appreciate that a number of motors and/or gearboxes can be used with the disclosed device 10, and that selection of the same will be dictated by the functions that the motors and/or gear boxes must perform.

The control unit 60 controls operation of the metering unit 30. The control unit 60 includes a counter (not shown), input controls 61, a first limit or activation switch 62, and a second limit or counting switch 64. For clarity, other necessary electronics known in the art are not shown in the FIGS. 1A-D.

The first activation switch 62, best shown in FIG. 1C, is located atop the device 10 and can have an external housing 63. Activation of the switch 62 is controlled by the compressing unit 80. The counting switch 64 is located adjacent the end 48 of the metering plate 40. The control unit 60 connects to a power supply (not shown) and is capable of providing power to the motor 52 when the activation switch 62 is activated by the compressing unit 80.

As the motor 52, gearbox 54, and slide crank 56 cause the metering plate 40 to move back and forth, the end 48 of the plate 40 makes repeated contact with the counting switch 64. The counter (not shown) within the control unit 60 is used to track each repeated contact to determine when a suitable number of strokes of the metering plate 40 have occurred in accordance with the user's input at input controls 61. In this regard, the input controls 61 on the control unit 60 allow the user to set an amount of tobacco to be metered from the hopper 20 to the compressing unit 80, which in turn ultimately affects the amount of tobacco 76 in the cigarette and/or its density. Using input controls 61, the user can input a number of strokes of the metering plate 40, or can select from one or more predetermined choices (e.g., by pressing input control buttons 61 labeled as “light,” “medium,” or “heavy,”) each associated with a number of stokes. Alternatively, the device may be preset to perform only a set number of metering plate 40 strokes and not allow the user to specify the same.

As best shown in the cross-section of FIG. 1C, the compressing unit 80 includes a compression chamber 90, a compression member 100, and a cranking unit 110. The compression chamber 90 is defined by first and second walls 92 and 94 connected between the sidewalls of the device. The first wall 92 defines a slit or opening 96 for the passage of tobacco 76 from the hopper 20 to the compression chamber 90 when the tobacco 76 is moved therethrough and passed the shear plate 46 by the serrated end 42 of the metering plate 40. (Of course, the edge of the first wall 92 proximate the opening 96 may also act as a shear plate 46, which otherwise may not be needed). Preferably, the slit 96 is chamfered adjacent the compression chamber 90. The second wall 94 of the chamber 90 defines an opening 98 for components of the compression member 100 to connect with components of the cranking unit 110.

The compression member 100 is vertically movably between the walls 92 and 94 of the compression chamber 90. The compression member 100 has a first end 102 capable of activating the activation switch 62 when the compression member 100 is moved to its top-most position within the chamber 90. The compression member 100 also has a second end 104 that defines a cylindrical surface, and which is used to compress and form tobacco in the compression chamber 90 into the proper cylindrical shape (“plug”) prior to insertion into the cigarette tube when the member 100 is moved to its bottom-most position within the chamber 90.

As best shown in FIG. 1B, the compression member 100 includes a clamp pin 106 extending from a side of the member 100. The clamp pin 106 fits into a slot 186 contained within a clamp rod 182 of the clamping unit 180. The clamp rod 182 is movable between tracks 184 outside the first sidewall 12. The end of the clamp rod 182 has a gripping member 188, which is preferably composed of an elastomer which is used to hold a cigarette tube to the device as will be described in more detail later. Through engagement of the clamp pin 106 in the slot 186 of the clamp rod 182, the gripping member 188 is movable relative to a tube holder or nozzle 178 (FIG. 1A) on an end block 176 of the injecting unit 150 to be described below.

While the gripping member 188 is shown as coupled to or in communication with the compression member 100, this is not strictly necessary. Instead, the gripping member 188 may constitute a separate device mounted on the exterior of the housing that allows a user to clamp the cigarette tube 70 to the device prior to operating the device. (See FIG. 10B, element 790).

As best shown in FIG. 1C, a cam pin 108 projects from the face of the compression member 100 through the aperture 98 defined in the wall 94 of the compression chamber 90. The cam pin 108 engages the cranking unit 110 for moving the compression member 100 within the chamber 90.

The cranking unit 110 includes a crank arm 112, a shaft 114, and a cam member 116. The crank arm 112 is attached to the shaft 114, which is rotatable on a bearing mount 16 of the body 11. The cam member 116 is also attached to the shaft 114 and is rotatable with the arm 112 and shaft 114. Additional bearings and washers (not shown) may be used between the cam member 116, mount 16, and shaft 114.

The cam member 116 defines an eccentric or spiral slot 118 (see FIGS. 1A and 1C) in which the cam pin 108 of the compression member 100 is inserted. A user uses a handle 113 on the crank arm 112 to rotate the cam member 116. With rotation of the cam member 116, the cam pin 108 moves within the eccentric slot 118, and the compression member 100 is moved up or down between the walls 92 and 94 of the chamber 90 depending on the direction of rotation of the crank arm 112.

In FIG. 1A, the crank arm 112 and cam member 116 are illustrated in an extreme counterclockwise position, and the compression member 100 is moved to its top-most position. When so positioned, the top end 102 of the compression member 100 engages the activation switch 62 (see FIG. 1C), as will be described in further detail later. When the crank arm 112 is rotated clockwise from the position shown in FIG. 1A, for example, the compression member 100 is moved down so that its bottom end 104 can compress against any loose tobacco at the bottom of the compression chamber 90.

As best shown in FIG. 1A, the injecting unit 150 includes a shuttle 160, a stop 170, spring 172, retainer 174, an end block 176, and a tube holder 178. As best shown in FIG. 1C, the shuttle 160 includes a trigger 162, an insertion member 164, and guides 166 and 168. The shuttle 160 is positioned below the compression chamber 90 and is movable along the guides 166 and 168. As best shown in FIG. 1D, the trigger 162 extends from a side of the shuttle 160 and is intended to engage with the arm 112 (FIG. 1C) of the cranking unit 110 as described below. The insertion member 164 is positioned between the guides 166 and 168 and has one end 165 attached to the shuttle 160. The insertion member 164 preferably defines a half-cylindrical surface that tapers towards its distal end. Such a shape is known in the art for facilitating the insertion of a compressed plug of tobacco in a cigarette tube.

The guides 166 and 168 fit into slots defined in the lower end of the walls 92 and 94 (FIG. 1C) and are movable therein for guiding movement of the shuttle 160. As best shown in FIG. 1A, the stop 170 is connected at an end of the shuttle 160 with a fastener 171. The spring 172 is interconnected between the stop 170 and the retainer 174, which is attached to the second side wall 14 of the body 11. When the spring 172 is not extended, the shuttle 160 is in an extreme lateral position (i.e., the right-most position in FIG. 1A), and the stop 170 engages the end block 176, which prevents the shuttle 160 from moving further towards the retainer 174.

When rotated in the clockwise direction, the crank arm 112 eventually engages the trigger 162 of the shuttle 160, stretches the spring 172, and moves the shuttle 160 towards the tube magazine 130. When so moved, and as best shown in FIG. 1D, the distal end of the insertion member 164 can then be disposed through the nozzle 178 attached to an opening of the end block 176.

As best shown in FIG. 1A, the tube magazine 130 is attached to the first side wall 12 and has a bottom surface 132 and two sides 134 and 136. The bottom surface 132 angles towards the injecting unit 150. A fold over 138 is formed on the open end of the bottom surface 132 adjacent the injecting unit 150 to hold cigarette tubes 70 against the bottom surface 132 and adjacent the injecting unit 150. The magazine 130 can hold a plurality of cigarette tubes 70.

With the benefit of the above description, operation of the disclosed device 10 will now be discussed with reference to FIGS. 2A-4.

Referring to FIGS. 2A-B, the device 10 is shown in various stages during the metering process in which an amount of tobacco 76 is being metered from the hopper 20 to the compression chamber 90. In FIG. 2A, the disclosed device 10 is shown in a side cross-section. In FIG. 2B, the disclosed device 10 is shown in a frontal view with certain components missing or in dotted lines to reveal internal components of the disclosed device 10. For example, the wall 94 and the guides 168 are removed so that the first wall 92, slit 96, and insertion member 164 are visible in FIG. 2B. Also, the first sidewall 12, clamp member 182, end block 176, and nozzle 178 are shown in cross-section.

During operation, a user fills the hopper 20 with a sufficient amount of loose tobacco 76, and positions several cigarette tubes 70 in the magazine 130 with their open paper end adjacent the sidewall 12. The user manually inserts an open end of the first tube 70 over the tube holder or nozzle 178 adjacent the compression chamber 90. Preferably, the tube holder 178 defines an angled opening as shown to facilitate insertion into the cylindrical paper portion 72 of the tube 70.

Using the input 61 of control unit 60, the user then selects a desired amount of tobacco for filling the tube 70 as discussed earlier. Then, the user turns the crank arm 112 to an extreme counterclockwise position as shown in FIG. 2B, which brings the top end 102 of the compression member 100 into contact with the activation switch 62, which in turn informs the control unit 60 that the metering unit 30 can be activated.

The user then activates an appropriate input 61 on the control unit 60 to start metering and to provide power to the motor 52. Rotation from the motor 52 is transferred through the gearbox 54 to the slide crank 56, etc., as described earlier, which ultimately causes the metering plate 40 to slide between the guide surfaces 32 and 34. As the serrated end 42 is repetitively moved passed the shear plate 46, an amount of loose tobacco 76 is moved from the hopper 20, through the slit 96 in wall 92, and ultimately to the compression chamber 90, as shown in FIG. 2A.

As noted above, not only does the holding wall 28 limit the amount of tobacco 76 at the bottom of the hopper 20, but it maintains the loose shreds of tobacco 76 adjacent the bottom surface 21 of the hopper 20 as the serrated end 42 of the plate 40 is pushed towards the compression chamber 90. Without this feature, the tobacco 76 might otherwise merely be pushed around in the hopper 20 without passing through the slit 96. Again, other means for biasing the tobacco 76 downward on the hopper 20, such as those discussed earlier, can be used.

The shear plate 46 serves the dual function of cutting excessively long shreds of the tobacco 76 and limiting the amount of tobacco capable of passing from the hopper 20 to the compression chamber 90. In any event, the metering plate 40 and the shear plate 46 can accommodate various styles or cuts of loose tobacco, such as shag or bulk cuts. Cutting of the tobacco (if needed depending on the tobacco used) is beneficial so that tobacco 76 compressed and inserted in the cigarette tube 70 has a predictable consistency. The tobacco 76 when ultimately inserted in the cigarette tube 70 preferably has a fine consistency which helps to maintain the integrity of the cigarette and make the tobacco 76 less likely to fall out of the tube 70 during handling or smoking. The shear plate 46 may be permanently attached to the wall 92 or may wholly constitute the wall 92. Alternatively, the shear plate 46 may be attached to the wall 92 in a manner where its vertical position can be modified by the user, which allows for adjustment of the amount of tobacco to be passed to the compression chamber 90 or the degree to which it is cut. Of course, the slit 96 would need to be larger that shown when used with an adjustable shear plate.

As the serrated end 42 of the metering plate 40 is drawn away from the shear plate 46 by the motor 52, more tobacco 76 is allowed to move to the bottom surface 21 of the hopper 20. With each backward draw, the second end 48 of the metering plate 40 activates the counting switch 64. The counter (not shown) in the control unit 60 counts each backward draw and cuts power to the motor 52 when the preset number of repeated draws has been reached by the metering plate 40. Consequently, a metered amount of tobacco is delivered to the compression chamber 90 and collects on the cylindrical surface of the injection member 164, as shown in FIG. 2B. The metered amount of tobacco moved from the hopper 20 to the compression chamber 90 depends on a number of variables, such as the dimensions of the metering plate 40, the hopper 20, the opening defined by the shear plate 46, the number of draws made with the metering plate 40, the cut of the tobacco used etc. Typically, a cigarette tube 70 can hold about 0.8-grams of tobacco. The metering plate 40 may make approximately 6 to 20 repetitive draws of loose tobacco 76 to meter such a sufficient amount of tobacco, and the entire metering process may only take about 15-seconds.

Referring to FIGS. 3A-3B, the disclosed device 10 is shown in various stages during the compression operation, i.e., in which the tobacco metered into the compression chamber 90 is compressed. As noted above, after the metering unit 30 has metered the desired amount of tobacco 76 onto the injection member 164, the control unit 60 shuts off the metering unit 30, at which point the user then rotates the cam arm 112 in a clockwise position. Such rotation of the cam arm 112 and affixed cam member 116 moves the compression member 100 downward within the compression chamber 90 through the interaction of the cam pin 108 and the eccentric groove 118 of the cam member 116. The cylindrical end 104 of the compression member 100 presses against the loose tobacco 76 collected on the insertion member 164, forming a substantially cylindrical plug of tobacco.

As the cam arm 112 is rotated and the compression member 100 is moved downward, the clamp pin 106 (FIG. 3B) eventually engages an end of the slot 186 defined in the clamp rod 182, which also moves the clamp rod 182 downward towards cigarette tube holding nozzle 178. The gripping member 188 on the end of the rod 182 is thus held against the paper portion 72 of the tube 70 installed on the nozzle 178. With the tube 70 firmly held in place in this manner, the process can continue to the injection operation, which is describe with reference to FIG. 4.

Referring to FIG. 4, as the user continues to rotate the arm 112 clockwise, the arm 112 eventually contacts the trigger 162 on the shuttle 160 to move it laterally (i.e., to the left in FIG. 4). Still further rotation overcomes the bias of the spring 172, and moves the insertion member 164 and compressed plug of tobacco 76, which is still compressed thereon by the bottom end 104 of the compression member 100. The distal end of the insertion member 164 passes through the nozzle 178 and into the cylindrical paper portion 72 of the cigarette tube 70. As noted earlier, the gripping member 188 holds the paper portion 72 in place during injection.

When the arm 112 and shuttle 160 reach an extreme lateral position (not show in FIG. 4), the user reverses rotation of the arm 112 (i.e., counterclockwise). The shuttle 160 and insertion member 164 retract from the tube 70 due to the bias of the spring 172, with the plug of tobacco 76 remaining in the cylindrical tubular portion 72. In addition, eventually the compression member 100 and clamping unit 180 are moved upwards. The filled cigarette tube 70 can then be removed from the nozzle 178 and the next tube 70 can be prepared for filling by slipping it over the nozzle 178. When the user rotates the arm 112 to an extreme counterclockwise position (FIG. 2B), the compression member 100 again engages the activation switch 62 so the entire procedure can be repeated for metering, compression, and injecting the next cigarette tube 70 in the magazine 130. Using the disclosed device 10, a user can fill approximately four cigarette tubes 70 within approximately one minute.

II. Second Embodiment

FIGS. 5A-5B illustrate second embodiments of a device 200 for filling cigarette tubes which are fully manual. More specifically, and in contrast to the first embodiment, the metering process in these second embodiments are performed manually by the user. For convenience, the same element numerals are in this second embodiment to represent substantially similar components disclosed with respect to the first embodiment, with discussion of such similar components omitted for brevity.

In FIG. 5A, the disclosed device 200 is partially exposed in a side view to reveal internal details. The disclosed device 200 includes a manually-operable metering unit for metering amounts of tobacco 76. The metering unit 230 includes guide surfaces 232 and 234, a metering plate 240, a handle 246, and a stop 248. As before, the metering plate 240 is movable between the guide surfaces 232 and 234. The metering plate 240 has a serrated and beveled end 242 movable in relation to the shear plate 46 for metering amounts of tobacco 76 from the hopper 20 to the compression chamber 90.

The handle 246 is attached to another end 244 of the plate 240 which extends beyond the body 11 of the device 200. The second or lower guide surface 234 also extends beyond the body 11 for guiding and supporting the plate 240. The lower guide surface 234 can also include side walls, such as the back wall 235 shown, for guiding the plate 240 and to prevent it from moving from side to side as it is moved from left to right. The stop 248 is positioned on the plate 240 to engage the body 11 to prevent over insertion of the plate 240.

To operate the metering unit 230, a user holds the handle 246 and draws the metering plate 240 back and forth to meter amounts of tobacco from the hopper 20 to the compression chamber 90. The other operations of the disclosed device 200 are similar to those described previously.

FIG. 5B shows an alternative to the use of the manual handle 246 of FIG. 5A. In FIG. 5B, a crank arm arrangement 250 is used. This arrangement is somewhat similar in its basic structure to the metering unit 30 disclosed in the first embodiment, the significant different being that no motor is used; instead the user rotates a crank arm 252 to cause the metering plate 240 to reciprocate. The metering plate 240 defines a lateral slot 248 contain an eccentric pin 258 affixed to a crank 256 affixed to the crank arm 252. By rotating the manual crank arm 252, the user can draw the metering plate 240 back and forth to meter tobacco from the hopper 20 to the compression chamber 90.

One skilled in the art will recognize that various bearings and supports can be used for the embodiments of FIGS. 5A and 5B.

III. Third Embodiment

FIGS. 6A-6B illustrate a third embodiment of a device 300 for filling cigarette tubes which is fully automated. Again, the same element numerals are used for substantially similar structures referenced earlier, which are not repeated here.

Device 300 includes a compression motor 310, a metering motor 350, an injection motor 370, and a control unit 360. Automated metering is substantially similar to that described with respect to the automated metering unit of the first embodiment, which is not reiterated here.

The components of the compression mechanism are also largely similar to those disclosed with respect to the first embodiment, except that the crank arm 112 has been replaced by compression motor 310 and a gearbox, which are not shown which are similar to those described previously, and which include a first gear shaft 312, a drive belt 314, and a second gear shaft 316. The motor and gearbox rotate the first gear shaft 312, which rotates the second gear shaft 316 with the drive belt 314. As the second gear shaft 316 is connected to the cam member 116, such rotation moves the compression member 100 and the clamp member 180 (FIG. 1B) as described previously. Specifically, rotating the gear shaft 312 in one direction causes compression of tobacco metered into the compression chamber, while rotation in the reverse direction causes the compression member 100 to engage the activation switch 62 (not shown) in housing 63.

As one skilled in the art will recognize, if the motor's shaft is connected directly to second gear shaft 316, first gear shaft 312 and drive belt 314 are not necessary. Moreover, although shown external to the housing for the device 300, the components of the compression mechanism can be configured to reside inside of the housing.

The injection motor 370 similarly includes a gearbox, which is not shown but which is similar to those described previously. The injection motor 370 includes a pinion 372, which intermeshes with teeth formed on a rack 374 attached to the shuttle 160. The motor and gearbox rotate the pinion 372, which in turn moves the rack 374 from left to right, i.e., towards or away from the cigarette tube magazine 130 as described previously. More specifically, by rotating the pinion 372 in one direction, the injection motor 370 moves the shuttle 160 toward the magazine 130 to inject previously-compressed tobacco into a waiting cigarette tube 70. Rotating the pinion 372 in a reverse direction returns the shuttle 160 to a position under the compression chamber 90.

Referring to FIG. 6B, an embodiment of the control unit 360 for the disclosed device 300 is schematically shown. The control unit 360 is capable of sequential operation and control of the metering motor 350, the compression motor 310, and the injection motor 370. A plurality of limit or contact switches 361-365 are used by the control unit 360 to determine the location of the metering plate 40, the compression member 100, and the shuttle 160 and to report such positions to the control unit 360. Although limit switches are used in the present embodiment of the control unit 360, one of ordinary skill in the art will readily recognize that a number of other position sensing devices known in the art can be used to sense or detect the location of the components. For example, Hall effect sensors, encoders, proximity switches, or optical switches can be used.

The control unit 360 is coupled to a power supply, which can be a battery source or a conventional commercial power source, and is coupled to the various switches and motors referenced earlier. Also typically present in the control unit 360 is an Application Specific Integrated Circuit (ASIC), a Programmable Logic Circuit (PLC), a microcontroller, or other similar non-integrated circuitry for receiving switch inputs and generating motor outputs, and which otherwise contains a suitable algorithm to run the metering, compression, and injection portions of the filling procedure in sequence. One preferable PLC used in the control unit is part number FP-e, distributed by Aromat Corporation of New Providence, N.J. As one skilled in the art will appreciate, should the integrated circuitry not be able to provide suitable current drive to drive the motors, a relay may be interposed as a switch between the outputs of the control unit 360 and the motors 310, 350, and 370 to pass DC regulated power to the motors. In any event, understanding the basic functions and sequences of events as disclosed herein, one skilled in the art can design such circuitry for the control unit 360 as a matter of course.

As before, the control unit 360 can have or be coupled to a user interface 380 comprising various input 381 such an on/off switch or various inputs such as buttons or a key pad, such as those used to select the quantity of tobacco to be placed in the cigarette as discussed earlier. The user interface may also include a LCD or dot matrix display 382 to provide the user instructions or otherwise inform the user of the status of the device or the filling operation. In its simplest embodiment, the user interface 380 need only comprise an on/off switch.

After affixing a tube 70 to the nozzle 178, the user selects at 381 the filling operation to be performed (e.g., to specify a “light” or “heavy” cigarette), or otherwise merely presses a button (e.g. an on/off switch) to perform a preset filling algorithm. At that point the counter in the control unit 360 is updated to define the number of metering strokes to be performed. (Alternatively, the control unit can be configured to perform metering strokes for a set period of time instead of a set number of strokes). The metering motor 350 is then activated to move the metering plate 40 back and forth. It is preferable prior to metering that the control unit 360 move the compression member 100 upward and shuttle 160 to the right (as shown), or otherwise verify that switches 362 and 364 are depressed to ensure that these components are in the right place and will not interfere with metering.

In one embodiment, when the counter sees that the switch 361 has been depressed by the specified number of strokes, the control unit 360 stops metering motor 350 and next activates the compression motor 310 to direct the compression member 100 (and clamping unit 180) downward. When this happens, switch 363 is depressed, and perhaps by first verifying that switch 364 has been depressed, the control unit 360 will then be signaled to engage the injection motor 370. At this point, the injection motor 370 moves the shuttle 160 to the left to inject the compressed tobacco plug into the waiting (and clamped) cigarette tube 70. The control unit will know that injection has occurred when it senses that switch 365 has been depressed. At that point, the control unit 360 initializes the device 300 for the next filling procedure by activating the motors 310 and 370 to move the compression member 100 and the shuttle 160 back to their starting positions.

One of ordinary skill in the art will appreciate that the motors must be capable of providing enough force or torque to move the components 40, 100, and 160 of the disclosed device 300 and/or to compress and inject the tobacco. Determination of sufficient capacities or ratings of motors, gearboxes, etc. would be a routine undertaking of one of ordinary skill in the art.

Although limit switches 361-365 are particularly useful, they may not be strictly necessary if motors 350, 310, and 370 constitute stepper motors or have encoders indicative of position and which can be interpreted by the control unit 360.

IV. Fourth Embodiment

Referring to FIG. 7, a fourth embodiment of a device 400 for filling cigarette tubes with metered amounts of tobacco is illustrated. Again, similar element numerals are used for similar components illustrated earlier.

As with the third embodiment, this fourth embodiment is capable of automated metering, automated compression, and automated injection of tobacco. However, this configuration provides a dual compression and injection motor 410 that performs both of these functions. Because the automated metering scheme and control unit 360 are similar to those described in earlier embodiments, they are not further discussed here.

The dual compression and injection motor 410 activates both the compressing unit 80 and the injecting unit 150, and preferably includes a gearbox, which is not shown but which may be similar to those described previously. As with the third embodiment, a first gear shaft 412, a drive belt 414, and a second gear shaft 416 are shown and which ultimately provide rotational movement to the second gear shaft 416. Such rotation rotates the cam member 116 to move the compression member 100 (and clamping unit 180) downward as described previously.

The cam member 116 has an arm 112 affixed to it as in the first embodiment, although this arm is not manually activated by the user. Instead, the arm 112 rotates by virtue of motorization of the second gear shaft 416, and after compression, comes into contact with trigger 162 to move the shuttle 160 to inject the tobacco as described earlier. In short, motor 410 performs both compression and injection in an automated fashion. Of course, this fourth embodiment also preferably has a control unit 360, which operates similarly to that described in the third embodiment, although simplified by virtue of this fourth's embodiment's two-step filling process (metering and compression/injection). (For example, and referring briefly to FIG. 6B, limit switches 363 and 364 might not be necessary in this fourth embodiment as it may only be necessary for the control unit 360 to know when the device is ready for metering (switch 362) and when injection is finished (switch 365)). Furthermore, as no manual activation is required, the moving components for this embodiment may all be made internal to the housing of the device 400.

V. Fifth Embodiment

More sophisticated fully-automated approaches may also be employed. For example, FIG. 8 shows a fifth embodiment of a device 500 for filling cigarette tubes with metered amounts of tobacco. This embodiment is largely similar to the third embodiment illustrated earlier. More specifically, the metering and injection hardware, and the aspects of control unit 360, are similar in this embodiment, and again, similar elements numerals are used to describe components introduced earlier. However, in this fifth embodiment, the compression hardware and algorithm are modified to allow the amount of tobacco 76 being compressed to be sensed to assess whether it is adequate. If the amount of tobacco sensed is inadequate, further metering strokes are performed, and quantity is again assessed via compression, as will be described in more detail later.

In this fifth embodiment, the compression motor 510 is oriented differently as in the third embodiment: in the third embodiment the gear shaft 312 of the motor was horizontal, whereas the gear shaft 512 in this embodiment is vertical. A suitable motor 510 for this embodiment includes part number 8322S002, manufactured by Pittman of Harleysville, Pa.

Gear shaft 512 is coupled to a pinion 514, which meets in a meshed teeth relationship with drive gear 516. Drive gear 516 is in turn coupled to a drive screw 518. The gear shaft 512 and drive screw 518 are coupled to the housing 550, but contain bearings to allow them to rotate. (The housing 550 is merely illustrative and may consist of several different components in a commercial embodiment. One skilled in the art will recognize that there are many ways of mounting the various components within the housing 550, and that such components will contain various through holes to allow motion of the internal components). The shaft of the drive screw 518 is threaded as shown, and has a traveling nut 520 with internal threads screwed to the threads on the drive screw 518. The traveling nut 520 is rigidly affixed to the compression member 100, and indeed may be made integral therewith. The compression member 100 and traveling nut 520 are affixed in the housing 550 within grooves (only partially shown for clarity) to keep their horizontal positions constant, much in the same way as was discussed with respect to FIG. 3A. So configured, operation of the motor 510 turns gear shaft 512, which in turn turns the drive shaft 518, and which in turn allows the traveling nut 520 and compression member to move vertically within the housing 550 of the device 500.

When the motor 510 is operated, the compression member is capable of moving a maximum vertical distance of D+Δ, which distance may be dictated by controlling the operation of the motor. This distance is also limited by a mechanical stop, such as the compression member 100 touching the compression chamber 90 or more likely the traveling nut 520's bottom touching the housing 550. When the nut 520 bottoms out against the housing, there is a possibility that the nut 520 will “bind” or “jam” against the housing, which is especially possible given that inertia of the drive shaft 518 will cause further tightening even after the motor 510 has shut off. To alleviate this problem, a spring 530 is positioned over the drive shaft 518, which is held is place between the housing 550 and a shaft collar 532 affixed to the drive shaft 518. When the nut 520 bottoms out against the housing, any further rotation of the drive shaft 518 will draw the shaft collar 532, and hence the drive shaft 518, upward by a small amount, which in turn will compress spring 530, and prevent binding of the nut 520.

In any event, Δ constitutes an overstroke distance, such that when the maximum distance of D+Δ is traversed by the compression member 100 and/or nut 520, the device 500 understands that not enough tobacco 76 (not shown) has been passed by the metering motor 350 to the compression chamber 90. This is understood by the device because traversing the maximum distance brings an actuator 522 on the traveling nut 520 into contact with the switch 363. In other words, when switch 363 is contacted, the control unit 360 understands that further metering of the tobacco is necessary to bring more tobacco to the compression chamber 90. (Of course, the control unit 360 must know when to query the status of the switch 363; this can be accomplished by knowing the time that it takes for the compression member 100 to traverse completely downward, and then programming the control unit 360 to query the switch 363 after the expiration of that time period). Accordingly, the control unit directs the compression member 100 upward, and the metering motor 350 is preferably activated for one additional metering stroke (although more than one stroke could be used). Thereafter, compression is again attempted through activation of motor 510. Should switch 363 again be contacted, additional metering is performed, and so on. Eventually, a sufficient amount of tobacco is metered into the compression chamber, and this additional bulk of tobacco prevents the compression member 100 from traversing the overstroke distance, Δ. (In fact, and assuming suitable limits to the motor 510's power, the motor 510 may stall). In other words, the compression member 100 eventually will only travel a distance of D, as shown in FIG. 8, which is not a sufficient distance to allow the actuator 522 to contact the switch 363. When this lack of contact of switch 363 is detected by the control unit 360, it understands that a suitable amount of tobacco has been metered, and accordingly that compression is now finished, and injection can begin through activation of the injection motor 370 as described earlier.

Thus, in this fifth embodiment, the device 500 can detect the amount of metered tobacco, and can adjust the amount of tobacco that is metered to ensure a suitable finished filled cigarette. Such an additional capability is especially beneficial when dealing with tobaccos of different cuts or consistencies, which may not meter at the same quantities per metering stroke, and therefore which may require adjustment by the device 500. Using dimensions for the metering system disclosed earlier, and as can be programmed in the control unit 360, it is preferred to initially perform five metering strokes, followed by compression and detection, followed if necessary by one additional metering stroke, followed again by compression and detection, and so on, until detection suggests a full compression chamber 90 ready for injection. However, this is not strictly necessary, and compression and detection can be performed after every metering stroke to simplify the algorithm, although of course initial metering strokes would be unlikely to provide a suitable amount of tobacco.

VI. Sixth Embodiment

FIG. 9A depicts a sixth embodiment of a device 600 for filling cigarette tubes with metered amounts of tobacco which is similar in many respects to the fifth embodiment discussed above. However, this sixth embodiment contains additional intelligence for determining whether an adequate amount of tobacco has been metered to the compression chamber 90.

In FIG. 9A, an additional switch 540 is disclosed, which, in conjunction with switch 363, assists in determining whether an adequate amount of tobacco has been metered, or whether additional metering is needed as discussed above. In this sixth embodiment, the traveling nut 520 is not rigidly coupled to the compression member 100. Instead, it is coupled by spring loaded plungers 550. In one embodiment, the plungers 550 resemble set screws having threads on their outsides which can be screwed into the nut 520 as shown in FIG. 9B. The plungers 550 contain an internal springs coupled to ball noses at their bottoms which can be depressed to compress the internal springs. Suitable plungers 550 include part number LK-1A, supplied by Reid Tool Supply Company of Muskegon, Mich.

The traveling nut 520 complete with the plungers 550 are positioned within a slot 570 formed in the compression member 100. This causes the plungers 550 to compress, which biases the top of the nut 520 against the top edge of the slot 570, and which exposes a small gap 580 between the bottom of the nut 520 and the bottom edge of the slot 570. In a preferred embodiment, this gap 580 is approximately 0.03-inches, although other spacings can be used. Although not all details of the housing 550 are shown as explained above in conjunction with the fifth embodiment, it will be understood that portions of the housing 550 are used to confine the lateral movement of the compression member 100 and traveling nut 520, which keeps the two from disconnecting during operation.

The plungers 550, once assembled in the nut 520 and once the nut is assembled within the compression member 100, are accessible through holes milled in the compression member 100 (not shown) to allow the plungers 550's height to be adjusted by a screwdriver if necessary. Such an adjustment feature may be beneficial in determining the optimal position of the plungers 550 in a new device, but in a commercial embodiment, it is envisioned that the proper depths and heights for the plungers 550 will be determined, and hence that the springs can merely reside in pockets within the nut 520. Any deformable material exhibiting spring-like properties could also be used, in lieu of plungers 550, such as elastomers, rubber nubs, etc. As used in this disclosure, “springs” should be understood as inclusive of all materials exhibit such spring-like properties.

As shown in FIG. 9B, a plurality of plungers 550 are used which span along the center portion of the length of the compression member 100 to provide even feedback from the compression member 100 along its length, a feature whose reasons will be made clear shortly. The actual length, L, of the traveling nut 520 may be approximately 0.75-inch, compared to the approximately 2.7-inch length of the compression member 100.

As with the fifth embodiment, the disclosed configuration allows the traveling nut 520 to drive the compression member 100 downward to compress tobacco within the compression chamber 90, but allows the compression member 100 to shift upward a gap 580's worth relative to the traveling nut 520 should the load produced by the tobacco in the compression chamber 90 be great enough to overcome the compressive force of the plungers 550. Whether the tobacco load is sufficient for injection is determined by the interaction of a second actuator 590 and its associated switch 540, as shown in FIG. 9A. The actuator 590 is capable of contacting the switch 540 when the compression member 100 is fully extended downward by the motor 510, i.e., through overstroke distance D+Δ as described earlier. Simultaneously, driving the compression member 100 through the overstroke distance will cause actuator 522 to contact switch 363 as described in conjunction with the fifth embodiment, although in this sixth embodiment switch 363 is not used to make an assessment of sufficient tobacco quantity in the compression chamber 90; that is the purpose of switch 540. Instead, switch 363 is used to merely inform the control unit 360 that the compression member 100 is fully extended and hence that switch 540 can be queried to assess tobacco quantity.

Thus, when the compression member 100 is fully extended, the load of the tobacco in the compression chamber 90 on the compression member 100 will determine whether the quantity of metered tobacco was sufficient, or if further metering strokes are needed. If the quantity of tobacco is insufficient, the tobacco will not place a sufficient upward force on the compression member 100, which in turn will not create a sufficient enough force on the springs in the plungers 550 to cause the compression member 100 to shift a gap 580 upward relative to the nut 520. Instead, the nut 520 will remain pinned against the upper edge of slot 570, and the actuator 590 will be brought into contact with switch 540. The condition of the switches (363 contacted, 540 contacted) is thus interpreted by the control unit 360 as an insufficient tobacco condition, and further metering is performed as discussed above with reference to the fifth embodiment. Eventually, when the quantity of the tobacco is sufficient within the compression chamber 90, the force of the tobacco will be sufficient to cause compression of the springs in the plungers 550, and will cause the compression member 100 to shift a gap 580 upward relative to the nut 520, which will prevent actuator 590 from contacting switch 540. The condition of the switches (363 contacted, 540 not contacted) is thus interpreted by the control unit 360 as a sufficient tobacco condition, and therefore that the injection process can now begin.

This sixth embodiment, while more complicated than the fifth embodiment, is believed preferable because it reduces the possibility of the control unit 360 making an improper assessment of tobacco quantity. For example, assume that something in the device has jammed and that the compression member 100 is prevented from a full downward extension. If this happens, the fifth embodiment, after the time for switch 363 assessment has passed, would see that the switch 363 had not been pressed and hence would erroneously determine that an adequate amount of tobacco was present in the compression chamber 90, that compression was complete, and that injection could commence. However, in the sixth embodiment, the jam would prevent switch 363 from ever becoming depressed, which the control unit 360 (after some time) would interpret as a error, and hence would not bother to query the condition of switch 540.

One skilled in the art will recognize that there are many different ways to mechanically configure the components of the device 600 to achieve the functionality described herein. For example, and as shown in FIG. 9C, which shows a plan view of the nut 520 and associated hardware with the motor 510 removed, the switches 363 and 540 could be placed at opposing edges and on the same side of the compression member 100, instead of at opposing sides as shown in FIG. 9A. In such a modification, the actuators 522 and 590 can be placed perpendicularly with respect to each other. Moreover, and as shown in FIG. 9C, the actuator 590 can be positioned through a hole 595 in one of the walls 94 (see FIG. 1C) which bind the compression member 100. (The compression member 100, which is behind the wall 94 in this view, is shown in dotted lines). Also shown in FIG. 9C is an opening 98 in the wall 94 though which the nut 520 communicates with the compression member 100, and which is analogous to the opening 98 shown in FIGS. 1A and 1C.

VII. Seventh Embodiment

In a seventh embodiment of a device 700 for filling cigarette tubes with metered amounts of tobacco, metering and compression are automated and combined into a single operation and are controlled by a single motor. This seventh embodiment, while similar in nature to the fifth and sixth embodiments in its ability to adjust tobacco quantity, is thus simpler and perhaps cheaper to implement as it does not require the additional complexity of three motors. Instead, only two motors are required: one to meter and compress, and one to inject.

The basic structure of device 700 is shown in FIGS. 10A-10B which respectively show side and end views of the device. Certain internal structural members have been omitted so as not to obfuscate important operative components, but one skilled in the art will understand that such additional structures will be present in a commercial device. Appropriate housing structures 710 can be made of any suitable materials such as metal or plastic. The hopper 20 for holding the tobacco 76 (not shown) is formed in the center of the device, and may have suitable downward tobacco biasing means as described earlier. Also shown in FIG. 10A are the user interface 380 portion of the control unit 360 which was described earlier, a metering/compression section 715, and an injection section 720. Also shown in FIG. 10B is the nozzle 178 onto which a cigarette tube 70 to be filled is affixed (tube magazine 130 not shown for convenience), and a hand-operated, spring-based elastomer-tipped gripping member 790 for holding the cigarette tube firmly to the nozzle 178.

Although the primary feature of interest in this seventh embodiment is in the metering/compression section 715, the injection section 720 is first discussed. The injection section 720 includes a motor 722 whose rotor is connected to a gear box 724 having a drive shaft 726. A combination motor/gear box product suitable for use in this regard is part number CHM-2445-IM, manufacture by Molon Motor and Coil Corporation of Rolling Meadows, Ill. The drive shaft 726 drives a gear 728 having teeth meshing with teeth on a rack 730 on an injection shuttle 732, which is similar to the injection shuttles disclosed earlier, although in this embodiment the shuttle 732 is rotated at 90 degrees. To track the end point positions of the shuttle 732, switches 364 and 365 are again used as in earlier embodiments. As one skilled in the art will understand, various adaptors can be used with the drive shaft 726 if necessary to couple it to the gear 728 and/or to allow the gear 728 to slip should the shuttle 732 become jammed. Otherwise, the injection section 720 and related components are similar to those discussed in earlier embodiments.

The basic scheme of the metering/compression section 715 is to pass a metering/compression member 735 across the bottom of the hopper 20 to meter tobacco to a compression chamber 740 and to use the same member 735 to compress the tobacco in the chamber 740 at the end of its stroke. In this regard, the metering/compression section 715, like the injector section 720, includes a motor 740, gear box 742, a drive shaft 744, a gear 746, and may also constitute Molon part number CHM-2445-IM disclosed above. The gear 746 contains teeth which mesh with teeth on a rack 748 which is rigidly coupled to a traveling shuttle 750. The traveling shuttle 750 is similar to the traveling nut 520 disclosed in the fifth and sixth embodiments in that it ultimately drives the metering/compression member 735, and may do so through a rigid coupling between the two (as in the fifth embodiment) or with a spring-biased coupling (as in the sixth embodiment). Illustrated herein is a spring-biased coupling arrangement, which, as noted earlier with respect to the sixth embodiment, provides better intelligence to the control unit 360 concerning whether adequate amounts of tobacco have been metered and whether injection can commence.

The metering/compression member 735 and its associated traveling shuttle 750 are shown in further detail in FIGS. 10C-10E. The metering/compression member 735 is preferably formed of metal and has a rectangular opening 755 formed therethrough to accompany the traveling shuttle 750. The traveling shuttle 750 is preferably formed of upper 760 and lower 761 pieces (FIG. 10E) affixed to each other by bolts 762 (FIG. 10C) or by other suitable fastening means. The upper 760 and lower 761 pieces may themselves be formed of other pieces affixed together, or may be forged or milled as shown; they are shown as solid integral pieces for simplicity. The upper piece 760 includes the rack 748 introduced earlier. As best seen in FIG. 10D, the lower piece 761 accompanies springs 764, which are similar in function to plungers 550 disclosed and discussed with respect to the sixth embodiment. Although only one spring 764 is shown, three springs are preferably used spanning partially across the width of the metering/compression member 735. The springs 764 appear in pockets 765 formed in the lower piece 761, which may be formed by milling holes in the piece 761, and then affixing a solid sub-piece 766 to the back of the holes as shown. As best shown in FIG. 10E, the width of the upper 760 and lower 761 pieces is wider than the opening 755 formed in the metering/compression member 735, such that when the two are bolted together (762), the member 735 will be confined therebetween. However, because the member 735 must be able to reciprocate between the two pieces 760, 761 of the traveling shuttle 750 as described below, the thicknesses of the various pieces are adjusted to allow such freedom of movement.

As best shown in FIG. 10D, the metering/compression member 735 is formed with a ledge 770 along its lower surface. The springs 764 are biased against this ledge 770. Because the metering/compression member 735 is moveable within the traveling shuttle 750, the effect of this spring bias is to push the shuttle 750 toward the left edge of the opening 755 formed in the member 735 as shown. Because the length of traveling shuttle 750 is slightly smaller than the length of the opening 755, such bias causes a gap 772 to form between the right edge of the opening 755 and the traveling shuttle 750, which is approximately 0.07-inches. However, because the traveling shuttle is held firm relative to the housing 710 by virtue of its connection to gear 746 (FIG. 10A), when a force is experienced on the right edge of the member 735, the bias of springs 764 can be overcome, and the member 735 will shift towards the left, which closes gap 772 on the right side of the opening 755 and reestablishes it on left side of the opening 755. In other words, and depending of the load experienced by the member 735, the member 735 can reciprocate from left to right relative to the traveling shuttle 750 through a gap 772's length, a property which is useful to assess whether a suitable amount of tobacco has been compressed in the compression chamber 740, as will be explained below.

The compression chamber 740, best shown in FIG. 10D, is in this seventh embodiment essentially cylindrical in shape. When the metering/compression member 735 is set in motion by gear 746, a semi-cylindrical leading edge 774 of the member 735 is drawn from left to right through the bottom of the hopper 20, thus collecting tobacco and moving it to the compression chamber 740. Once the member 735 reaches its overstroked or fully extended condition (as described earlier), this leading edge is 774 brought to (or when overstroked, preferably slightly passed) a gap 776 formed in the upper cylindrical surface of the compression chamber 740 to essentially complete the chamber 740's cylindrical surface and to define a cylindrical compressed plug of tobacco suitable for injection. Although not strictly necessary, it is preferable to form the gap 776 in an upper portion of the chamber 740, and most preferably from 270 to 360 degrees. In this way, when tobacco is moved into the chamber 740, no tobacco gap will be formed in the top of the chamber 740, and instead, the tobacco will gradually be encouraged to move clockwise within the chamber as depicted by the arrow in FIG. 10D. In short, formation of the gap 776 and leading edge 774 in this manner ensures that a complete and cylindrical plug of tobacco is formed. Moreover, the sharpness of the top of the leading edge 774 also assists in shedding or cutting the tobacco prior to entry into the chamber 740, and thus the use of a scalloped edge (disclosed earlier) is not necessary. To further ensure proper cutting of tobacco as it passes from the hopper 20 to the compression chamber 740, the front wall 791 of the hopper 20 can be formed with a bladed shape (not shown).

As best shown in FIGS. 10A and 10D, a roller 778 rotatably affixed to the housing 710 provides support to the traveling shuttle 750, and ultimately metering/compression member 735, while still permitting these components to move horizontally within the device 700.

The metering/compression process in this seventh embodiment is similar in nature to that used in the sixth embodiment and uses a similar switch arrangement to assess the adequacy of the quantity of tobacco in the compression chamber 740; hence, the switches used are labeled with the same element numerals. More specifically, and referring to FIG. 10A, three switches are used for metering/compression: switch 362 informs the control unit 360 when the traveling shuttle 750 is at its home or fully retracted position (to the left in FIG. 10A); switch 363 informs the control unit when the shuttle 750 is fully extended (to the right in FIG. 10A); and switch 540 assesses tobacco load to either inform the control unit that further metering is necessary or that injection can commence. Switches 362 and 363 are activated by an actuator 780, which is most easily seen in FIG. 10C. As seen in FIGS. 10A and 10B, this actuator 780 interacts with the contacts on these switches as the shuttle 750 slides between its fully retracted and fully extended positions, thus informing the control unit 360 when these end points have been reached.

The contact on switch 540, by contrast, is activated by the metering/compression member 735 itself, as best seen in FIGS. 10A and 10B. More specifically, and assuming negligible tobacco load in the compression chamber 740, switch 540 is positioned within the housing so that its contact is always depressed by the member 735 passing overhead, except when the member 735 is at it fully extended (right most) position. Even more specifically, when fully extended, the contact on switch 540 is at most a gap 772's length away from the left edge of the member 735. So positioned, the switch 540 can determine whether the quantity of tobacco in the compression chamber 740 is sufficient. If the quantity is not sufficient, no or little load will be placed by the tobacco on the member 735, and the springs 764 (FIG. 10D) between the member 735 and traveling shuttle 750 will not appreciably compress. As a result, the member 735 will not shift to the left relative to the shuttle 750, and the contact on switch 540 will not be depressed. If the quantity is sufficient, sufficient load will be placed by the tobacco on the member 735 to compress the springs 764 between the member 735 and traveling shuttle 750. As a result, the member 735 shifts to the left relative to the shuttle 750, which allows the left edge of the member 735 to remain engaged with the contact on switch 540. Accordingly, the control unit 360 interprets the switches as follows: when switch 363, is depressed, the control unit knows that the traveling shuttle 750 is fully extended and that it is appropriate to query the status of switch 540; if switch 540 is not depressed, further metering is necessary and the member is retracted for (at least) an additional metering stroke; if switch 540 is depressed, further metering is not necessary, and injection can begin.

Because metering and compression are performed by the same member 735 in this embodiment, the algorithm employed by the control unit 360 is simplified. For example, there is no reason for control unit 360 to initially perform some pre-set amount of metering strokes, and only later start assessing the adequacy tobacco quantity as discussed above with reference to the fifth and sixth embodiments. In this embodiment, every stroke of member 735 can perform the quantity assessment by querying the status of switch 540, even though obviously the first strokes are unlikely to have moved a sufficient quantity of tobacco.

VIII. Eighth Embodiment

Referring to FIGS. 11A-11D, an eighth embodiment of an automated device 800 for filling cigarette tubes with metered amounts of tobacco is illustrated. As with previous embodiments, the automated device 800 includes a housing 802, a control unit 806, a metering/compression section 810, and an injection section 820. The injection section 820 is similar to previous embodiments, such as injection section 720 of FIG. 10A, and includes a motor 822, a gear box 824, a drive shaft 826, a gear 828, and an injection member 830. The injection member 830 has a rack 832 and an injection shuttle 834. The gear 828 engages the rack 832 of the injection shuttle 834, which is similar to the injection shuttles disclosed earlier.

The metering/compression section 810 is similar to previous embodiments, and metering and compression are again automated and combined into a single operation controlled by a single motor 812 and a gear box 814. Furthermore, the device 800 is similar in nature to the fifth, sixth, and seventh embodiments in its ability to adjust tobacco quantity. However, features of interest of this device 800 include a scotch yoke 850 having a delay, a metering/compression assembly 860 having dual plates, and a quantity-adjusting mechanism 870 having an adjustment knob 880 and other components. The scotch yoke 850 couples the shaft 815 of the gear box 814 to the metering/compression assembly 860. During operation, rotation of the motor 812 in conjunction with the scotch yoke 850 reciprocates the metering/compression assembly 860 across the bottom of the hopper 20. In turn, the metering/compression assembly 860 meters tobacco from the hopper 20 to the compression chamber 840 and compresses the tobacco in the compression chamber 840. The quantity-adjusting mechanism 870 is used to adjust the quantity of tobacco metered and compressed during operation.

Isolated features of the scotch yoke 850 and the metering/compression assembly 860 are shown in the perspective view of FIG. 11B. The scotch yoke 850, which is generally similar to that disclosed above with reference to FIGS. 1C, 2A, and 3A, includes an intermediate member 852, an eccentrically located pin 854, and a traveling shuttle 856. The metering/compression assembly 860 has upper and lower plates 862 and 864. The upper plate 862 is preferably made of metal, and the lower plate 864 is preferably made of a plastic with a low coefficient of friction, such as ultra-high molecular weight polyethylene (UHMW).

With respect to the scotch yoke 850, the intermediate member 852 is coupled to the shaft 815 of the gearbox (not shown), and the eccentrically located pin 854 is attached to the intermediate member 852 off axis from the shaft 815. The eccentrically located pin 854 is positioned in a slot 858 of the traveling shuttle 856. Preferably, the pin 854 has a bearing or the like to reduce friction with the sides of the slot 858. Although the present embodiment has the pin 854 positioned in the slot 858 of the traveling shuttle 856, the pin 854 in another alternative can be positioned directly within a slot defined in the upper plate 862 as in previous embodiments of scotch yokes disclosed herein, which would eliminate the need for the traveling shuttle 856.

The traveling shuttle 856 is attached to the upper plate 862 of the metering/compression assembly 860 so that they move together during operation. However, the lower plate 864 is not directly attached to the upper plate 862 or the traveling shuttle 852. As best shown in the partial view of FIG. 11C, the lower plate 864 is sandwiched between the upper plate 862 and a horizontal structural surface 804 of the device 800. A spring component 866 having a plurality of spring members 869 is attached to the end of the upper plate 862. The spring members 869 engage the back end of the lower plate 864 so that the lower plate 864 moves with the upper plate 862 but can also move relative to the upper plate 862 by overcoming the bias of the spring members 869.

Features of the quantity-adjusting mechanism 870 are shown in the side view of FIG. 11C and the bottom view of FIG. 11D. The quantity-adjusting mechanism 870 includes an affixed wall 872, adjustment screws 874 and 876, and an adjustment knob 880. The adjustment screws 874 and 876 on the affixed wall 872 are primarily used to calibrate the metering and compression of the device 800 as described below. By contrast, the adjustment knob 880 is used by an operator to fine-tune the metering and compression during operation of the device 800.

As noted above, the device 800 is similar in nature to the fifth, sixth, and seventh embodiments in its ability to adjust tobacco quantity. In this respect, the device 800, as best shown in FIG. 11C, has a first switch 890 and a second switch 892, which are used in conjunction with the control unit 806. The first switch 890 is activated by the traveling shuttle 856 of the scotch yoke 850 when the metering/compression assembly 860 is moved to its advanced position during a metering stroke. Alternatively, the first switch 890 can be activated by a tab (not shown) attached to the upper plate 862 or can be activated by the intermediate member 852 when rotated to move the metering/compression assembly 860 to its fully advanced position during a metering stroke. The second switch 892 is not necessarily activated when the assembly 860 reaches its fully advanced position. Rather, activation of this second switch 892 is adjusted by the adjustment screw 876 on the affixed wall 872 and by the adjustment knob 880, as detailed below.

As shown in FIGS. 11C-11D, the affixed wall 872 is attached to the bottom of the lower plate 864 so that it extends through a window 805 defined in the horizontal structural member 804 on which the lower plate 864 reciprocates. The first adjustment screw 874 is threaded through the affixed wall 872 so that its distal end can engage the side of the window 805 when the lower plate 864 is reciprocated towards its fully advanced position (i.e., to the right in FIGS. 11C and 11D). Thus, adjustment of this first screw 874 adjusts the final advanced position of the lower plate 864, which affects the metering and compression of tobacco in the chamber 840. The second adjustment screw 876 is threaded through the affixed wall 872 so that its distal end can engage the second switch 892 when the lower plate 864 is reciprocated towards its advanced position. Thus, adjustment of this second screw 876 adjusts when the second switch 892 is activated or not, which also affects the metering and compression of tobacco in the chamber 840.

As noted previously, the adjustment knob 880 allows an operator to fine-tune the metering and compression of the device 800. As shown in the bottom view of FIG. 11D, the adjustment knob 880 is attached to a side of the device 800 and has a shaft 882 with an eccentric end 884. The second switch 892 is attached to the horizontal structural member 804 by a fastener 893 about which the second switch 892 can pivot. Turning the adjustment knob 880 rotates the eccentric pin 884, which alters the pivot of the second switch 892 about fastener 893. Thus, turning the knob 880 adjusts the point of engagement between the second screw 876 with the second switch 892, which assesses the load of tobacco in the chamber 840 and informs the control unit (806; FIG. 11A) whether further metering is necessary or whether injection can commence.

Operation of the device 800 to meter and compress tobacco will now be discussed briefly with reference to FIG. 11C. The scotch yoke 850 causes the first and second plates 862 and 864 to reciprocate and move tobacco from the hopper 20 to the compression chamber 840. In its fully advanced position, the traveling shuttle 856 engages the first switch 890, which informs the control unit 806 that the metering/compression assembly 860 has completed a metering stroke (to the right in FIG. 11C). When this first switch 890 is activated, the control unit 806 queries the second switch 892 positioned on the underside of the horizontal structural component 804. If the second switch 892 is activated while the first switch 890 is activated, then the control unit 806 determines that there is insufficient tobacco in the compression chamber 840, and the device 800 proceeds with one or more additional metering strokes.

During each metering stroke, the leading edges 863, 865 of the plates 862, 864 essentially complete the cylindrical surface of the compression chamber 840 and form the tobacco into a cylindrical compressed plug suitable for injection. Because the upper plate 862 is directly coupled to the scotch yoke 850, the upper plate 862 is encouraged to reach a fully advanced position when reciprocated towards the chamber 840. By contrast, the lower plate 864 being spring biased is capable of receding slightly by a gap G provided by springs 869 of spring member 866. When tobacco is being metered and compressed in the chamber 840, the fully advancing upper plate 862 along with the biased lower plate 864 can gradually encourage the tobacco to rotate somewhat clockwise within the chamber 840, which can ensure that a complete and cylindrical plug of tobacco is formed. In addition, the upper and lower plates 862 and 864 tend to form a more even plug (e.g., a dense, cylindrical plug) of tobacco in the compression chamber 840.

Ultimately, the quantity of tobacco in the chamber 840 will be sufficient after the metering/compression assembly 860 reciprocates through a number of strokes. During a “final” metering stroke, the force experienced on the leading edge 865 of the lower plate 864 overcomes the bias of the springs 869. As a result, the lower plate 864 recedes slightly, and the second screw 876 fails to activate the second switch 892. During this “final stroke,” the traveling shuttle 856 activates the first switch 890, and the control unit 806 queries the second switch 892, which is not activated during this stroke. Thus, the control unit 806 determines that there is sufficient tobacco in the compression chamber 840.

Once a sufficient quantity of tobacco has been determined, the control unit 806 initiates the injection process. During the injection process, the metering/compression assembly 860 preferably “lingers” in its fully advanced position. As best shown in FIG. 11B, the slot 858 in the traveling shuttle 856 preferably defines a delay or angled contour 859. During injection, the eccentrically located pin 854 is positioned at this delay 859 which forces the leading edges 863 and 865 to further compress the plug of tobacco in the compression chamber (840; FIG. 11A) and hold the compressed plug against the injection blade (not shown) as the blade injects the plug into the cigarette tube. Other operations of the injection process proceeds in a similar manner to previous embodiments and are not described again here.

IX. Ninth Embodiment

Referring to FIGS. 12A-12H, a ninth embodiment of an automated device 900 for filling cigarette tubes with metered amounts of tobacco is illustrated. This embodiment of the device 900 is similar to other embodiments of the automated devices disclosed herein, and more particularly to the eight embodiment of FIGS. 11A-11D. Due to such similarities, similar reference numbers are used to indicate like components between embodiments. For the sake of brevity, like components between the present device 900 and other embodiments of the present disclosure will not be discussed in detail below, and the present discussion of the device 900 incorporates the disclosure of the other embodiments.

Discussion of the device 900 will focus on additional features of the scotch yoke 850, the metering/compression assembly 860, the quantity-adjusting mechanism 870, and other components. For simplicity, some components of the device 900 are not shown in FIGS. 12A-12H. As best shown in FIGS. 12A and 12C, the device 900 has a block 902 having an upper block portion 903 a attaching to a lower block portion 903 b. The block 902 holds the metering motor 812 and gear box 814, the injection motor 822 and gear box 824, the metering assembly 860, the injection member 830, and the quantity-adjusting 880. As shown in FIG. 12C, for example, the metering assembly 860 having the upper and lower plates 862 and 864 is positioned between the upper and lower block portions 903 a and 903 b. As shown in FIG. 12A, portions of the adjustment mechanism 870 are attached to the side of the block 902.

As best shown in FIG. 12F, the upper block portion 903 a defines a lower portion of the hopper 20, which holds tobacco (not shown) to be metered. The upper and lower plates 862 and 864 of the metering/compression assembly 860 are reciprocated back and forth below the hopper 20. Tobacco is moved from the hopper 20 to the compression chamber, where ends of the plates 862 and 864 compress the tobacco in much the same manner as discussed above with reference to the eighth embodiment of device 800 shown in FIGS. 11A-11D.

As noted in other embodiments, the scotch yoke 850 is used to reciprocate the metering assembly 860, and a control unit (not shown) discussed previously is used to control and detect the reciprocating movement of the metering assembly 860. In the eight embodiment of the device 800 as shown in FIGS. 11A, for example, a switch (890) makes contact with the traveling shuttle (856) attached to the upper plate (862) to detect the forward compression position of the metering assembly (860). In contrast to this arrangement and as best shown in FIG. 12B, the present embodiment of the scotch yoke 850 includes an arm 853 a extending from the intermediate member 852 of the scotch yoke 850. A flag 853 b extends upward from this arm 853 a. As the intermediate member 852 is rotated during operation, the flag 853 b interrupts a photo interrupt switch 990, which is used queried to determine the position of the metering assembly 860 and more particularly the forward compression position of the upper plate 862.

As noted in other embodiments, such as device 700 shown in FIG. 10A, for example, movement of the injection member (732) is detected by contact switches (364, 365) to detect the position of the injection member (732) during the injection step. In contrast to this arrangement and as best shown in FIGS. 12E and 12G, the present device 900 has a flag 833 positioned on the shuttle 832 of the injection member 830, which is held within slots or chambers 904 a and 904 b formed by the upper and lower block portions 903 a and 903 b. (The slots or chambers 904 a and 904 b are also shown in the exploded view of FIG. 12C). When the injection shuttle 832 is moved (e.g., to the right and left in FIG. 12G) during the injection step, flag 833 interrupts photo interrupt switches 964 and 965, which are queried to detect the position of the injection shuttle 832.

The metering/compression assembly 860 in the present device 900 is similar to other embodiments disclosed herein. As best shown in FIG. 12C, for example, the upper plate 862, which is preferably metal, defines the slot 858 of the scotch yoke 850, and the slot 858 has a delay (not labeled), which is similar to previous embodiments. The upper plate 862 is reciprocated by the scotch yoke 850 and is positioned against the lower plate 864, which is preferably composed of plastic, such as nylon or UHMW. As before, movement of the upper plate 862 moves the lower plate 864 during operation.

The assembly 860 of the present device 900 also has additional or different features. A plurality of tabs 910 and 912 on the rear end of the upper plate 862 extend downward from the plate 860. The outer tabs 910 at the side edges of the plate 862 engage a leaf spring 940 coupled to the lower plate 864. The engagement of the outer tabs 910 and the ends of the leaf spring 940 tend to force the lower plate 864 in a forward compression direction, which is to the right in FIG. 12C. A central tab 912 engages the lower plate 864 when the upper plate 862 is in a fully forward compression position. A limiter 920 on the lower plate 864 engages in a groove 922 of the lower block portion 903 b, which limits forward and back movement of the lower plate 864 when reciprocated. The use of the tabs 910 and 912 can help overcome disadvantages associated with stacking of precision errors.

The lower plate 864 defines a hemispherical slot 921 to accommodate the pin 854 of the scotch yoke 850. The lower plate 864 also includes a rear portion 930 extending below and beyond the portion of the lower plate 864 having the leaf spring 940. The rear portion 930 defines a slot for holding a neoprene bumper 932 that engages the upper plate 862 when the upper plate 862 is moved in the retracted position. The rear portion 930 of the lower plate 862 also includes an adjustment nut 934, which is used to fine-tune the adjustment mechanism 870 as will be now explained below.

As best shown in the detail view of FIG. 12H, the adjustment mechanism 870 includes a knob 980, a linkage 984, and a limit switch 992. The adjustment knob 980 is positioned in slots defined in the block 902. (The slots are shown in the exploded view of FIG. 12C at 905 a and 905 b). The linkage 984 has one end pivotally attached to a pivot point 985 on the block 902. The limit switch 992 is attached to the other end of the linkage 984 and pivots about the pivot point 985. The adjustment knob 980 has an eccentric surface 982 that engages a cam surface 986 of the linkage 984 and thereby adjusts the pivot location of the limit switch 992. A spring 987 biases the linkage 984 and pushes the cam surface 986 against the eccentric surface 982 of the knob 980.

The limit switch 992 has a contact 993 that is capable of being engaged by the adjustment screw 934 attached to the rear portion 930 of the lower plate 864. By adjusting the pivoted location of the limit switch 992, the point when the limit switch 992 detects or does not detect engagement with the lower plate 864 can be adjusted. The adjustment screw 934 allows for fine-tuning of the engagement point.

As discussed in other embodiments, detection of the forward compression position of the lower plate 864 by limit switch 992 can signify that an insufficient quantity of tobacco has yet been metered and compressed by the device 900. When a sufficient quantity has been metered and compressed, the photo interrupt (990; FIG. 12B) is interrupted by the flag 853 b on the arm 853 a of the scotch yoke 850, which indicates full forward position of the upper plate 862. If the limit switch 992 on the quantity-adjusting mechanism 870 is not engaged by the screw 934 on the lower plate 864 when the photo interrupt (990; FIG. 12B) is queried, then the amount of tobacco metered and compressed may be sufficient.

In addition to the components shown in FIGS. 12A-12H, the present device 900 has additional components, such as a housing, a control unit, portions of the hopper 20, and other components, which have not been shown in the FIGS. 12A-12H and have not discussed above. Nevertheless, the present device 900 can include such components and incorporates the other discussions of such components. With the benefit of the discussion of the upper and lower plates 862 and 864 in the present embodiment of the device 900, it will be appreciated that the term “plate” as used in the disclosure and claims for these components does not necessarily indicated a planar, flat, or rectilinear component.

X. Tenth Embodiment

Referring to FIGS. 13A-13B, a tenth embodiment of an automated device 1000 for filling cigarette tubes with metered amounts of tobacco is illustrated in front and back perspective views. Some features of the device 1000 are similar to those discussed above with reference to the eighth embodiment of FIGS. 11A-11D so that like reference numerals are used for like components. A feature of interest in this device 1000, however, is a loader 1050 used to hold the cigarette tubes to be filled with the device 1000. The loader 1050 is preferably automated but may be manually operated.

As shown in FIG. 13A, the loader 1050, which is cylindrical, has one end that fits adjacent the housing 1002 of the device 1000 and preferably fits within a recess 1004 defined in the side of the housing 1002. The loader 1050 is removable from the device 1000 so that an operator can fill the loader 1050 with cigarette tubes, position the loader 1050 on the device 1000, sequentially fill the tubes by operating the device 1000, and remove the loader 1050 from the device 1000 when all of the tubes have been filled.

To hold the removable loader 1050 on the device 1000, a lower set of wheels 1010 and an upper wheel 1020 engage the cylindrical loader 1050, hold it adjacent to the housing 1002, and allow it to rotate about its axis. A lever mechanism 1022 is attached to the upper wheel 1020 to engage and disengage the upper wheel 1020 from the loader 1050, which allows the loader 1050 to be removed from the device 1000.

Isolated features of the loader 1050 are shown in the detailed views of FIGS. 14A and 14B. The cylindrical loader 1050 preferably defines a central hollow 1052, which accommodates portions of the injector during operation of the device 1000, as described below. The loader 1050 also defines a groove 1054 around one end so that the loader 1050 has a rim 1055, which is held by the wheels (1010 & 1020; FIGS. 13A-13B) of the device 1000. Twenty chambers 1056 for holding cigarette tubes 70 are defined in the loader 1050 from one end to the other, and tubular nozzles 1053 with angled tips are positioned within the groove 1054 and are attached to the rim 1055. Ends of the cigarette tubes 70 inserted into the chambers 1056 fit onto these nozzles 1053, which are used to grip the tubes 70 when being filled.

Additional features of the device 1000 are shown in the partial view of FIG. 15A, which shows a portion of the device 1000 without the loader so that details of the recess 1004, the lower wheels 1010, the upper wheel 1020, openings 1005 and 1006, and a gripping element 1014 are visible. The recess 1004 in the housing of the device 1050 is preferably oblong, which allows the cylindrical loader to be easily positioned into and removed from the recess 1004. The lower wheels 1010 are partially positioned in the recess 1004 so that they can fit into the groove (1054; FIG. 14A) of the loader 1050. The upper wheel 1020 is moveable relative to the lower wheels 1010 by the lever mechanism 1022 so that the loader 1050 can be engaged and disengaged by the upper wheel 1020.

The first opening 1005 in the housing 1002 allows the insertion blade 836 of the injection member 830 to extend from the device 1000 and into the end of an adjacent cigarette tube when held there. The gripping element 1014 with an elastomeric end is positioned adjacent the opening 1005 to engage the end of a cigarette tube. The second opening 1006 in the housing 1002 allows portion of the injection member 830 to extend out of the device 1000 during the injections step. As alluded to above, this portion of the injection member 830 passing through the opening 1006 also passes into the hollow (1052; FIG. 14A) of the loader 1050 when positioned against the housing 1002.

In addition to the above features, the device 1000 includes an advancing arm 1060 and a positioning pin 1032, which are used when the loader 1050 is held adjacent the housing 1002 as shown in FIG. 15B. As described below, the advancing arm 1060 is automated to rotate the loader 1050, and the positioning pin 1032 is automated to ensure that the loader 1050 is properly aligned before the injection step.

The loader 1050 is rotated during operation of the device 1000 by movement of the metering/compression assembly 860. During operation, the metering motor 812 is operated, and the metering/compression assembly 860 makes its first forward stroke for metering tobacco. A portion 870 of the assembly 860 engages a portion 1062 of the advancing arm 1060, causing the arm 1060 to also move forward (i.e., to the right in FIG. 15B). While moving, the upward angled end of the arm 1060 engages a slot 1057 of the loader 1050, and the movement of the arm 1060 rotates the loader 1050 in the counter clockwise direction by an increment of one chamber 1056. Thus, once the loader 1050 has been rotated, the next chamber 1056 having a cigarette tube (not shown) to be filled is aligned with the injection opening (1005; FIG. 15A) of the housing 1002, and the elastomeric end of the gripping member 1014 engages an end of the cigarette tube in the aligned chamber 1056.

After its first stroke, the metering/compression assembly 860 is retracted, but the advancing arm 1060 remains in its forward position until after the injection step. As noted below, a locking mechanism or releasable catch is used to hold the arm 1060 in its forward position. Then, the metering/compression assembly 860 is reciprocated through a plurality of strokes until enough tobacco has been metered. On its final stroke, the assembly 860 is held in its advanced position to compress the tobacco on the injection blade 836. Then, a solenoid (not shown) coupled to the positioning pin 1032 pushes it out from the housing 1002 and partially into one of the chambers 1056 to ensure correct alignment of the chamber 1056 whose tube is being filled with the injection opening (1005; FIG. 15A) and the injection blade 836. The solenoid (not shown) is then deactivated, and a spring (not shown) causes the positioning pin 1032 to retract from the chamber 1056. However, other alignment devices can be used. For example, a spring-loaded pin positioned in the housing 1002 can similarly be used to fit into one of the chambers 1056 to ensure correct alignment. Alternatively, a leaf spring attached outside the housing 1002 can engage the slots 1057 of the loader 1050 to ensure correct alignment.

With the loader 1050 aligned and the plug being compressed, the injection step then begins, and the injection motor 822, the gear 828, and the rack 832 move the injection shuttle 834. The injection blade 836 with the compressed plug of tobacco is passed through the injection opening (1005; FIG. 15A) and into the cigarette tube in the aligned chamber 1056. While the injection blade 836 is inserted into the aligned cigarette tube, the metering/compression assembly 860 is retracted, and the advancing arm 1060 is allowed to retract to its initial position (i.e., to the left in FIG. 15B). In its backward movement, the upward angled end of the arm 1060 slips out of the slot 1057 of the loader 1050 that it once occupied so that the end can engage the next slot 1057 when the arm 1060 is eventually moved forward again for the next cigarette tube. Finally, the injection blade 836 is retracted, leaving the compressed plug of tobacco in the cigarette tube in the loader 1050. Once done, the entire process can be repeated to fill another cigarette tube in the loader 1050.

Additional features of the device 1000 are shown in the bottom view in FIG. 15C. These additional features show how the metering/compression assembly 860 moves the advancing arm 1060 with its first stroke and how the advancing arm 1060 remains in an advanced position until the injection step. As shown, the advancing arm 1060 has an extending end 1061 for engaging the slots 1057 in the loader 1050. A sliding body 1064 is attached to this extending end 1061, and rails 1065 hold the sliding body 1064 adjacent the horizontal structural surface 804 above which the metering/compression assembly 860 reciprocates.

To advance the arm 1060 during a first metering stroke, a downward extending member 870 attached to the metering/compression assembly 860 engages an end of the sliding body 1064 and pushes the arm 1060 when the assembly 860 moves. To hold the arm 1060 in its fully advanced position after the first metering stroke, the other end of the sliding body 1064 has a catch 1066 that can lock against a retaining wall 1068 contained in the device 800. For example, the catch 1066 is made of spring steel with a hooked end that can fit within an opening or slot 1069 of the retaining wall 1068. When the sliding body 1064 reaches its fully advanced position, the hooked end passes through the slot 1069 and engages the other side of the wall 1068 to hold the sliding body 1064 in its advanced position. This prevents the advancing arm 1060 from being biased by a spring (not shown) back to its retracted position. As noted previously, the hooked end of the catch 1066 can then hold the advancing arm 1060 forward during the various strokes of the metering/compression assembly 860.

To release the advancing arm 1060, the injection member 830 has a pin 837 extending downward (i.e., extending up from the page in the bottom view of FIG. 15C). When the injection member 830 (e.g., rack 832, shuttle 834, and blade 836) is advanced forward during its injection stroke (i.e., to the left in FIG. 15C), the pin 837 deflects the catch 1066, causing the hooked end to come free from the retaining wall 1068 and allowing the spring (not shown) to slide the advancing arm 1060 to its retracted position. Preferably, the catch 1066 has an angled side 1067 for engagement with the deflecting pin 837.

As discussed above, the loader 1050 is automated, and the loader 1050 is rotated by movement of the metering/compression assembly 860. Referring now to FIGS. 16A-16B, a manually operated embodiment of the loader 1050 for the device 1000 is illustrated in an elevational view and a top cross-sectional view. The manual loader 1050 is similar in some respects to the previous embodiment disclosed above so that like reference numerals are used for similar components. In contrast to the previous embodiment, however, the manual loader 1050 is attached to the housing 1002 with a shaft 1051 and fasteners 1059, and the loader 1050 is manually operated by an operator turning the loader 1050 after each cigarette tube is filled. In addition, the manual loader 1050 holds ten cigarette tubes 70.

The loader 1050 can be affixed to the housing 1002 by the shaft 1051 so that the operator must insert and remove the cigarette tubes 70 with the loader 1050 attached to the device 1000. Alternatively, one fastener 1059 on the end of the shaft 1051 may be releasable, allowing for the manual loader 1050 to be removed to insert and remove cigarette tubes 70 from the chambers 1056. Preferably, the manual loader 1050 is attached to the housing 1000 so that the loader 1050 and shaft 1051 do not interfere with other components of the device 1000. For example, the shaft 1051 attaches to the housing 1002 so that is not aligned with the path of the metering/compression assembly 860, which is shown in the top view of FIG. 16B. Furthermore, the outer edge of the loader 1050 as shown in FIG. 16A does not interfere with the portions of the injection member 830 that pass through the opening 1006 in the housing 1002 during the injection step.

During operation of the device 1000, the operator manually turns the loader 1050 to align an empty cigarette tube in a chamber 1056 with the injection opening 1005 and injection blade 836 of the device 1000. To ensure proper alignment of the chambers 1056 with the opening 1005, a spring-loaded pin 1033 attached to the housing 1002 projects into an adjacent chamber 1056, and the operator can overcome the bias of this pin 1033 when turning the manual loader 1050 by hand.

Other automated embodiments for the loader 1050 can use an actuator to rotate the loader 1050. In FIG. 17A, for example, a motor 1080 having a wheel or gear 1082 attached can be used to rotate the loader 1050. The motor 1080, which can be a stepper motor, in conjunction with the wheel 1082, rotates the loader 1050 during operation, and the spring-loaded pin 1033 ensures proper alignment of the chambers 1056 with the injection opening 1005. The motor 1080 is preferably controlled by a controller (not shown) and is actuated at an appropriate point during operation of the device 1000.

In FIG. 17B, another embodiment of the loader 1050 is automated by a solenoid 1090 having a movable arm 1092. The solenoid 1090 moves the arm 1092, which engages slots 1057 to rotate the loader 1050 during operation. Again, the spring-loaded pin 1033 can ensure proper alignment of the chambers 1056 with the injection opening 1005. The solenoid 1090 is preferably controlled by a controller (not shown) and is actuated at an appropriate point during operation of the device 1000.

XI. Conclusion

The foregoing embodiments show several different configurations of devices for filling cigarette tubes with metered amounts of tobacco, which are either fully manual, partially automatic, or fully automatic. Certain features, details, and configurations were disclosed in conjunction with each embodiment. However, one skilled in the art will understand that such features, details, and configurations can be used with the various different embodiments, even if such features, details, and configurations were not specifically mentioned in conjunction with a particular embodiment, and that this disclosure contemplates various combinations of the features, details, and configurations disclosed herein. More specifically, it is intended that such features, details, and configurations are covered by this patent to the extent that they come within the scope of the following claims or the equivalents thereof. 

1. A device for filling a plurality of cigarette tubes with tobacco, comprising: a hopper for holding loose tobacco; a loader for holding a plurality of cigarette tubes, the loader being movable to position each of the cigarette tubes in communication with a compression chamber of the device; a movable assembly for moving loose tobacco from the hopper to the compression chamber and for compressing the loose tobacco in the compression chamber; and an injector for moving the compressed tobacco from the compression chamber to a cigarette tube held in the loader and positioned in communication with the compression chamber.
 2. The device of claim 1, further comprising means for automating the movement of the loader.
 3. The device of claim 1, further comprising a moveable arm for moving the moveable loader, the moveable arm being moveable in a first direction by movement of the moveable assembly.
 4. The device of claim 3, wherein the moveable loader is rotatable, and wherein movement of the moveable arm in the first direction rotates the loader.
 5. The device of claim 3, wherein the moveable arm comprises a releasable catch holding the moveable arm in the first direction.
 6. The device of claim 5, wherein movement of the moveable injector releases the releasable catch.
 7. The device of claim 1, wherein the moveable loader is manually operated.
 8. The device of claim 1, further comprising an actuator moving the moveable loader to position the cigarette tubes in communication with the compression chamber.
 9. The device of claim 1, wherein the loader comprises a cylinder having one end positioning adjacent the compression chamber and defining a plurality of chambers for holding the cigarette tubes.
 10. The device of claim 9, wherein the end of the loader positioning adjacent the compression chamber defines a circumferential groove, and wherein the device comprises a plurality of wheels attached to the device and engaging the circumferential groove of the loader to hold the loader on the device.
 11. The device of claim 10, wherein at least one of the wheels is movable for removal of the loader from the device.
 12. The device of claim 1, further comprising means for ensuring alignment of a chamber of the loader with the injector.
 13. The device of claim 1, wherein the moveable assembly comprises: a movable metering member for moving loose tobacco from the hopper to the compression chamber, and a moveable compression member for compressing the loose tobacco in the compression chamber.
 14. The device of claim 1, wherein the moveable assembly comprises a first moveable member for both moving loose tobacco from the hopper to the compression chamber and compressing the loose tobacco in the compression chamber.
 15. The device of claim 1, wherein the movable assembly comprises: a first plate coupled to a motor for moving the movable assembly along a first axis to a compression position, and a second plate coupled to the first plate by a biasing member which allows the compression position of the second plate to vary along the first axis in response to a load produced by tobacco in the compression chamber.
 16. The device of claim 15, wherein the biasing member comprises a leaf spring coupled to the second plate, and wherein the first plate comprises tabs to engage the leaf spring on the second plate.
 17. The device of claim 15, further comprising a switch for determining the variance in the compression position of the second plate in response to the load.
 18. The device of claim 17, further comprising an adjustment mechanism for varying the location of the switch, comprising: a pivotable linkage having the switch attached thereto and having a cam surface, and a rotatable knob having an eccentric surface for engaging the cam surface, wherein a portion of the second plate is capable of engaging the switch to change the status of the switch.
 19. A device for filling at least one cigarette tube with tobacco, comprising: a hopper for holding loose tobacco; a movable assembly for moving loose tobacco from the hopper to the compression chamber and for compressing the loose tobacco in the compression chamber, the movable assembly comprising a first plate and a second plate stacked adjacent one another, the second plate being movable relative to the first plate; and an injector for moving the compressed tobacco from the compression chamber to the cigarette tube in communication with the compression chamber.
 20. The device of claim 19, further comprising a loader for holding the at least one cigarette tube, the moveable loader being moveable to position the cigarette tube in communication with the compression chamber.
 21. The device of claim 20, wherein movement of the movable assembly moves the moveable loader.
 22. The device of claim 19, wherein the movable assembly and the injector are respectively automated in their movement by a first motor and an injection motor.
 23. The device of claim 19, wherein: the first plate is coupled to a motor for moving the movable assembly along a first axis to a compression position, and the second plate is coupled to the first plate by a biasing member which allows the compression position of the second plate to vary along the first axis in response to a load produced by tobacco in the compression chamber.
 24. The device of claim 23, wherein the biasing member comprises a leaf spring coupled to the second plate, and wherein the first plate comprises tabs to engage the leaf spring on the second plate.
 25. The device of claim 23, comprising a scotch yoke coupling the first plate to the motor.
 26. The device of claim 25, wherein the scotch yoke defines a delay causing the movable assembly to linger in the compression position.
 27. The device of claim 23, further comprising a first switch for determining whether the moveable assembly has moved to the compression position.
 28. The device of claim 27, further comprising a second switch for determining the variance in the compression position of the second plate in response to the load.
 29. The device of claim 28, further comprising an adjustment mechanism for varying a location of the second switch, the adjustment mechanism comprising: a pivotable linkage having the second switch attached thereto and having a cam surface, and a rotatable knob having an eccentric surface for engaging the cam surface, wherein a portion of the second plate is capable of actuating the second switch to change the status of the second switch.
 30. The device of claim 28, further comprising a control unit for querying the second switch only after the first switch has been actuated.
 31. The device of claim 19, further comprising a control unit for automating movement of the moveable assembly and the injector in sequence in accordance with an algorithm.
 32. The device of claim 31, wherein the control unit provides for additional metering by the moveable assembly if an insufficient quantity of tobacco has been assessed.
 33. The device of claim 19, wherein the moveable assembly reciprocates through a plurality of strokes to move the loose tobacco from the hopper to the compression chamber. 